JP5131331B2 - Liquid crystal display - Google Patents

Description

  The present invention relates to a liquid crystal display device capable of displaying a three-dimensional image.

  Conventionally, as a liquid crystal display device for displaying a three-dimensional image, an image for the right eye is displayed by every other column of pixels of the liquid crystal display element, and an image for the left eye is displayed by every other column of pixels. A lenticular that distributes an image and an image for the left eye into the right eye direction and the left eye direction of the display observer between the light emitted from the pixels in one row of the liquid crystal display element and the light emitted from the pixels in the other row The right eye and the left eye of the observer are made to observe through a lens or a parallax barrier formed in a stripe shape by alternately arranging a plurality of transmission parts and light shielding parts parallel to the pixel rows of the liquid crystal display element. (See Patent Documents 1, 2, and 3).

Japanese Laid-Open Patent Publication No. 3-19889 Japanese Patent Laid-Open No. 7-005455 Japanese Patent Laid-Open No. 10-268230

  However, since the conventional liquid crystal display device displays the image for the right eye by every other row of pixels of the liquid crystal display element and the image for the left eye by every other row of pixels, The dot pitch of both images for the eye is as coarse as twice the pixel pitch of the liquid crystal display element, so that a high-resolution three-dimensional image cannot be displayed.

  In addition, in the conventional liquid crystal display device, a lenticular lens having a lens pitch corresponding to the pixel pitch of the liquid crystal display element, or a parallax barrier having a transmissive portion pitch corresponding to the pixel pitch, and each lens portion or transmissive portion of the lenticular lens are The pixels in each row of the liquid crystal display elements must be arranged with high precision in a predetermined positional relationship, and thus are difficult to manufacture.

  An object of the present invention is to provide a liquid crystal display device that can display a three-dimensional image with high resolution and can be easily manufactured.

According to the first aspect of the present invention, the reflective polarizing film disposed so as to bend in a predetermined direction, and the light emission region is different from the first region and the first region of the reflective polarizing film. A first image projection means arranged to face the second region, and a light emission region in the third region of the reflective polarizing film and a fourth region different from the third region. Second image projecting means arranged so as to face each other and the reflective polarizing film interposed between the first image projecting means and the first image projecting means, The inner surface of the reflective polarizing film in the second region is set as a projection surface, and the light emitted from the first image projection means is on the optical path from the first region to the second region. The second image is arranged such that one region is located. The shadow unit is configured such that the inner surface of the reflective polarizing film in the fourth region is set as a projection surface, and the light emitted by the second image projection unit is on the optical path from the fourth region to the fourth region. The third region is arranged so as to be located in the center .

According to a second aspect of the present invention, in the liquid crystal display device according to the first aspect, the first image projection unit emits light that is transmitted through the first region and reflected by the second region. The second image projecting unit emits light that is transmitted through the third region and reflected by the fourth region.

According to the present invention, a high-resolution three-dimensional image can be displayed and can be easily manufactured.

1 is a perspective view of a liquid crystal display device showing a first embodiment of the present invention. FIG. 3 is a diagram illustrating the principle of displaying a three-dimensional image by the liquid crystal display device according to the first embodiment. The perspective view of the liquid crystal display device which shows 2nd Example of this invention. The display principle figure of the three-dimensional image by the liquid crystal display device of a 2nd Example.

(First embodiment)
1 and 2 show a first embodiment of the present invention, in which FIG. 1 is a perspective view of a liquid crystal display device, and FIG. 2 is a principle diagram for displaying a three-dimensional image by the liquid crystal display device.

  As shown in FIG. 1, this liquid crystal display device comprises a film having a front surface 2 facing the display viewing side and a rear surface 3 on the opposite side, and the transmission axes in two directions perpendicular to each other along the film surface. Of the two linearly polarized light components of incident light 1a and the reflection axis 1b that are orthogonal to each other, the linearly polarized light component parallel to the transmission axis 1a is transmitted and the linearly polarized light component parallel to the reflection axis 1b is reflected. Cylindrical screen 1 having optical characteristics and curved in a direction retreating from the both ends toward the opposite side from the observation side, and a liquid crystal display element that displays an image by controlling light transmission 5 and a surface light source 9 for supplying light to the liquid crystal display element 5, first and second image display means 4 A and 4 B for emitting linearly polarized image light from the liquid crystal display element 5, and the first 1 and one of the second image display means 4A, 4B Right-eye image to display, and a display driving means for displaying the left-eye image to the other in.

  The screen 1 is the same as a reflective polarizing film which is a kind of optical film, and its cross-sectional structure is not shown, but isotropic thin film (optically isotropic thin film) made of polyethylene naphthalate copolymer or the like. ) And anisotropic thin films (optically anisotropic thin films) consisting of a multi-layered film in which multiple layers are laminated alternately with the same refractive index in all anisotropic thin films in the same direction. .

  The screen 1 has a transmission axis 1a in a direction in which the refractive index of the anisotropic thin film is the same as the refractive index of the isotropic thin film, and the refractive index of the anisotropic thin film is refracted by the isotropic thin film. The reflection axis 1a is in a direction different from the rate, that is, in a direction orthogonal to the transmission axis 1a, and two straight lines perpendicular to each other of the incident light with respect to light incident from any of the front and rear surfaces 2 and 3 thereof. Among the polarized light components, one linearly polarized light component having a vibration surface along the transmission axis 1a is transmitted, and the other linearly polarized light component having a vibration surface along the reflection axis 1b is alternately laminated. The optical characteristic which reflects in each interface of an anisotropic thin film and an anisotropic thin film is shown. Hereinafter, this screen 1 is referred to as a reflective polarizing screen.

  The liquid crystal display elements 5 of the first and second image display means 4A and 4B each have a liquid crystal cell 6 having a plurality of pixels (not shown) arranged in a matrix in the row direction and the column direction. It consists of a pair of polarizing plates 7 and 8 on the incident side and the emission side, which are arranged with the liquid crystal cell 6 interposed therebetween.

  The liquid crystal cell 6 is of an active matrix type using, for example, a TFT (thin film transistor) as an active element, and its internal structure is not shown, but the inner surfaces facing each other of a pair of transparent substrates facing each other with a liquid crystal layer interposed therebetween. In addition, a plurality of transparent pixel electrodes arranged in a matrix in the row direction and the column direction, a plurality of TFTs respectively connected to these pixel electrodes, and a plurality of gates supplying gate signals to the TFTs in each row A single film that is provided with wiring and a plurality of data wirings for supplying data signals to the TFTs of each column, and that forms a plurality of pixels on the inner surface of the other substrate by regions facing the plurality of pixel electrodes, respectively. In this configuration, a transparent counter electrode is provided.

  Further, the liquid crystal display elements 5 of the first and second image display means 4A and 4B each have, for example, liquid crystal molecules of the liquid crystal layer of the liquid crystal cell 6 at a twist angle of substantially 90 degrees between the pair of substrates. It is a twisted nematic (TN) type liquid crystal display element, and the pair of polarizing plates 7 and 8 on the incident side and the emission side thereof have their transmission axes substantially orthogonal to each other or substantially parallel to each other. Are arranged.

  Further, each of the surface light sources 9 of the first and second image display means 4A and 4B has a uniform intensity distribution over the entire screen area in which a plurality of pixels of the liquid crystal display element 5 are arranged in a matrix. The surface light source 9 emits light on one end face of a transparent plate having an area facing the entire screen area of the liquid crystal display element 5. An incident end surface is formed, an exit surface is formed on one plate surface of the transparent plate, and the other plate surface reflects light incident on the transparent plate from the incident end surface and emits the light from the exit surface. And a light source element such as a cold-cathode tube or a light-emitting diode disposed to face the incident end face of the light guide plate.

  The surface light source 9 is arranged on the incident surface side of the liquid crystal display element 5 so that the exit surface of the light guide plate is closely opposed to the incident surface of the liquid crystal display element 5 (the outer surface of the incident-side polarizing plate 7). ing.

  That is, each of the first and second image display means 4A and 4B causes the light emitted from the surface light source 9 to enter the liquid crystal display element 5 from the incident surface side, and transmits the light to the liquid crystal cell 6. Are controlled according to image data written in each pixel (electric field applied between the electrodes of each pixel) to display an image on the liquid crystal display element 5, from the exit surface of the liquid crystal display element 5. Then, linearly polarized image light parallel to the transmission axis 8 a of the emission side polarizing plate 8 is emitted.

  Of the first and second image display means 4A and 4B, the first image display means 4A is rearward on the left end side when viewed from one end side of the reflective polarizing screen 1, for example, the front side of the screen 1. In addition, in the state where the left edge when viewed from the emission side of the liquid crystal display element 5 is close to the edge of the screen 1, the emission direction of the image light from the first image display means 4A is set to the screen. 1 through a region closer to the first image display means 4A than the central portion of the rear surface 3, and into a region opposite to the first image display means 4A side relative to the central portion of the front surface 2 of the screen 1. The second image display means 4B is arranged in the direction of incidence, and the second image display means 4B is disposed on the other end side of the reflective polarizing screen 1, that is, on the rear side of the right end when viewed from the front side of the screen 1. Front edge on the right when viewed from the exit side In the state of being close to the edge of the screen 1, the emission direction of the image light from the second image display unit 4 </ b> B is closer to the second image display unit 4 </ b> B side than the center portion of the rear surface 3 of the screen 1. It is arranged in such a direction as to enter the region opposite to the second image display means 4B side from the central portion of the front surface 2 of the screen 1 through the region.

  The display driving means for displaying the right-eye image on one of the first and second image display means 4A and 4B and displaying the left-eye image on the other drives the first image display means 4A. The first display driving circuit 10A and the second display driving circuit 10B for driving the second image display means 4B.

  Each of these display drive circuits 10A and 10B is not shown in configuration, but each gate wiring of the liquid crystal cell 6 of the liquid crystal display element 5 is sequentially selected to supply a gate signal, corresponding to the selection of each gate wiring. A display element driving unit for supplying data signals corresponding to right-eye or left-eye image information supplied from the outside to each data wiring and writing image data to each pixel; A surface light source driving unit that turns on the light emitting element, and of these display driving circuits 10A and 10B, a first image display arranged behind the left end as viewed from the front side of the reflective polarizing screen 1 The display element driving unit of the first display driving circuit 10A for driving the means 4A writes the right eye image data on the liquid crystal display element 5 of the first image display means 4A to display the right eye image. Configured as The display element driving unit of the second display driving circuit 10B for driving the second image display means 4B disposed on the rear side of the right end when viewed from the front side of the reflective polarizing screen 1 is configured to display the second image display. The left eye image data is written to the liquid crystal display element 5 of the means 4B to display the left eye image.

  Each of the liquid crystal display elements 5 of the first and second image display means 4A and 4B is a color image display element having three color filters of red, green, and blue respectively corresponding to a plurality of pixels. A field sequential display element that displays a color image without a color filter may be used. When the liquid crystal display element 5 is a color image display element, the surfaces of the first and second image display means 4A and 4B are used. The light source 9 emits white light, and the first and second display drive circuits 10A and 10B write red, green and blue image data into each pixel of the liquid crystal display element 5. What is necessary is just to comprise.

  When the liquid crystal display element 5 is a field sequential display element, the surface light sources 9 of the first and second image display means 4A and 4B selectively emit light of three colors red, green and blue, respectively. The first and second display drive circuits 10A and 10B are configured to transfer unit color image data of three colors of red, green, and blue to the liquid crystal during one frame for displaying one color image. What is necessary is just to comprise so that the light of the color corresponding to the unit color image data may be radiate | emitted from the said surface light source 9 for every writing of each pixel of the display element 5 sequentially, and writing of the unit color image data of each color.

  In this liquid crystal display device, the direction of vibration of the linearly polarized light emitted from the first and second image display means 4A and 4B (the emission-side polarizing plate 8 of the liquid crystal display element 5 of each of the image display means 4A and 4B). The direction parallel to the transmission axis 8a) and the directions of the transmission axis 1a and the reflection axis 1b of the reflective polarizing screen 1 are emitted from the first and second image display means 4A and 4B to the screen 1. After that, the linearly polarized light incident from the surface 3 passes through the screen 1 and enters the opposite region of the screen 1 from the front surface 2, and the light is reflected by the screen 1 to the observation side. It is set to emit.

  That is, in this liquid crystal display device, the first image display unit 4A and the second image display unit 4B are arranged in the direction of the transmission axis 1a viewed from the rear surface side of the screen 1, and the first and second image display units 4B. The vibration directions of the linearly polarized light emitted from the first and second image display means 4A and 4B when the emission surfaces of the image display means 4A and 4B are opposed to the rear surface of the screen 1 are substantially parallel. It arranges so that it may become.

  The liquid crystal display device of this embodiment displays a three-dimensional image in front of the face of the display observer C (see FIG. 2), and the reflective polarizing screen 1 and the first and second image display means 4A. , 4B are provided on a mounting body (not shown) mounted in front of the eyes of the display observer C, for example.

  The liquid crystal display device of this embodiment displays a right-eye image on the first image display means 4A arranged at the rear of the left end side when viewed from the front side of the reflective polarizing screen 1, and the reflective polarizing screen 1 By displaying the image for the left eye on the second image display means 4B disposed on the rear side of the right end as viewed from the front side, these image lights are displayed on the respective image display means 4A rather than the central portion of the screen 1. , 4B is incident from the rear surface 3, exits from the first image display means 4A, passes through the screen 1, and is opposite to the first image display means 4A side of the front surface 2 thereof. The image light for the right eye that has entered the region is reflected by the screen 1 toward the right eye of the display observer C, exits from the second image display means 4B, passes through the screen 1 and passes through the screen 2 on the front surface 2 thereof. Second image displayer The image light for the left eye that has entered the region on the opposite side to the 4B side is reflected by the screen 1 toward the left eye of the display observer C, and the display observer C has a three-dimensional feeling like a real thing. In this liquid crystal display device, the curvature of the cylindrical reflective polarizing screen 1, the reflective polarizing screen 1, the first and second image display means 4A, 4B, and Is output from first image display means 4A that displays an image for the right eye arranged behind the left end when viewed from the front side of the screen 1, passes through the screen 1, and passes through the front surface 2 thereof. Is reflected from the right side of the display observer C, and is emitted from the second image display means 4B that displays an image for the left eye arranged behind the right end when viewed from the front side of the screen 1. Through the screen 1 It has set the light incident on the front surface 2 to reflect the left eye direction of the display observer C.

  The display of a three-dimensional image by this liquid crystal display device will be described with reference to FIG. 2. This liquid crystal display device has an image for the right eye and a left image on the first image display means 4A and the second image display means 4B. The right-eye image light emitted from the first image display means 4A disposed behind the left end when viewed from the front side of the reflective polarizing screen 1 is displayed along the path. As shown by a solid line in FIG. 2, the rear surface 3 enters the region of the first image display means 4A from the central portion of the screen 1 and is seen from the front side of the reflective polarizing screen 1 on the right end side. The image light for the left eye emitted from the second image display means 4B arranged behind the second image display is more than the center of the screen 1, as shown by the broken line in FIG. Incident from the rear surface 3 into the region of the means 4B

  Each of the image light for the right eye and the image light for the left eye has a vibration surface parallel to the transmission axis 8a of the output side polarizing plate 8 of the liquid crystal display element 5 of the first and second image display means 4A and 4B. In this liquid crystal display device, the vibration direction seen from the emission side of the linearly polarized light emitted from the first image display means 4A and the emission of the linearly polarized light emitted from the second image display means 4B. The vibration direction viewed from the side is substantially parallel, the direction of the transmission axis 1a viewed from the rear surface 3 of the reflective polarizing screen 1, and the exit surfaces of the first and second image display means 4A and 4B. Is substantially parallel to the vibration direction of the linearly polarized light emitted from the first and second image display means 4A and 4B when facing the rear surface 3 of the screen 1. Exit from the second image display means 4A, 4B Wherein said linearly polarized incident from the rear surface 3 in the screen 1 is transmitted through the screen 1 respectively incident from the front surface 2 to the area of the opposite side of the screen 1 in.

  The directions of the transmission axis 1a and the reflection axis 1b viewed from the front surface 2 of the reflective polarizing screen 1 are shifted by 90 degrees with respect to the directions of the transmission axis 1a and the reflection axis 1b viewed from the rear surface 3 of the screen 1. Therefore, the linearly polarized light incident on the screen 1 from the rear surface 3 and transmitted through the screen 1 and incident on the opposite side region of the front surface 2 (transmission axis 1a viewed from the rear surface 3 of the screen 1) 2 is substantially parallel to the reflection axis 1b viewed from the front surface 2 of the reflective polarizing screen 1, as shown by the chain line arrow a in FIG. The linearly polarized light that is transmitted and incident on the front surface 2 is reflected by the screen 1 to the observation side.

  That is, in this liquid crystal display device, the first image display means 4A and the second image display means 4B are viewed from the rear surface side of the screen 1, the direction of the transmission axis 1a, and the first and second image display means 4B. The vibration directions of the linearly polarized light emitted from the first and second image display means 4A and 4B when the emission surfaces of the image display means 4A and 4B are opposed to the rear surface of the screen 1 are substantially parallel. The linearly polarized light emitted from the first and second image display means 4A and 4B and incident on the screen 1 from the rear surface 3 is transmitted through the screen 1 and transmitted through the screen 1 respectively. The screen 1 can be incident on the area opposite to the image display means 4A, 4B side of the screen 1 from the front surface 2, and the light can be reflected by the screen 1 and emitted to the observation side.

  In this liquid crystal display device, the curvature of the reflective polarizing screen 1 and the positional relationship between the reflective polarizing screen 1 and the first and second image display means 4A and 4B are set as described above. The right-eye image light emitted from the first image display means 4A, transmitted through the reflective polarizing screen 1 and incident on the area of the front surface 2 opposite to the first image display means 4A side is Reflected in the right eye direction of the display observer C by the screen 1, emitted from the second image display means 4B, transmitted through the reflective polarizing screen 1, and the second image display means 4B side of the front surface 2 The left-eye image light incident on the opposite region is reflected by the screen 1 in the direction of the left eye of the display observer C, and causes the display observer C to observe a three-dimensional image having a stereoscopic effect like the real thing. be able to.

  As described above, the liquid crystal display device has the transmission axis 1a and the reflection axis 1b in two directions orthogonal to each other, and is a straight line parallel to the transmission axis 1a out of the two linearly polarized light components of incident light orthogonal to each other. Reflected polarized light having an optical characteristic of transmitting a polarized light component and reflecting a linearly polarized light component parallel to the reflection axis 1b and curved in a direction retreating from both ends toward the opposite side from the viewing side toward the center. The first image display means 4A and the second image display means 4B that emit linearly polarized image light on the rear side on one end side and the rear side on the other end side of the screen 1 are respectively displayed on the image display means 4A and 4B. The image display means 4A, 4B passes through a region closer to the image display means 4A, 4B than the center portion of the rear surface 3 of the screen 1 and the image display means 4A, 4B rather than the center portion of the front surface 2 of the screen 1. On the opposite side And the direction of vibration of the linearly polarized light emitted from the first and second image display means 4A and 4B and the directions of the transmission axis 1a and the reflection axis 1b of the screen 1 The linearly polarized light emitted from the first and second image display means 4A and 4B and incident on the screen 1 from the rear surface 3 passes through the screen 1 and is opposite to the area on the screen 1. And the light is reflected by the screen 1 and emitted to the observation side, and the right-eye image is applied to one of the first and second image display means 4A and 4B. The image for the left eye is displayed on the other side, and these image lights are incident on the respective image display means side areas from the rear side of the central portion of the screen, thereby allowing one image table to be displayed. The right eye image light emitted from the means 4A and transmitted through the screen 1 and incident on the front surface 2 is reflected in the direction of the right eye of the display observer C, and emitted from the other image display means 4B and transmitted through the screen 1. Then, the image light for the left eye incident on the front surface 2 is reflected in the direction of the left eye of the display observer C so that the display observer C can observe a three-dimensional image having a stereoscopic effect like the real thing. Is.

  Therefore, according to this liquid crystal display device, the first image display means and the second image display means display a precise right eye image and left eye image each having the same dot pitch as the pixel pitch of the liquid crystal display element 5. A high-resolution three-dimensional image can be displayed.

  In addition, this liquid crystal display device displays the right eye image on one of the first and second image display means 4A and 4B and the left eye image on the other, and these image lights are displayed on the reflective polarizing screen 1. Therefore, the curvature of the reflective polarizing screen 1 and the positional relationship between the reflective polarizing screen 1 and the first and second image display means 4A and 4B are expressed as an image for the right eye. Light emitted from the image display means for display, reflected through the screen and incident on the front surface thereof is reflected in the direction of the right eye of the display observer, and emitted from the image display means for displaying the image for the left eye. A three-dimensional image can be displayed by setting so that the light transmitted through and incident on the front surface is reflected in the direction of the left eye of the display observer, and thus can be easily manufactured.

  The liquid crystal display device can display not only the three-dimensional image but also a two-dimensional image. In this case, the same image is displayed on both the first and second image display means 4A and 4B. Alternatively, an image is displayed on one of the first and second image display means 4A and 4B, and the other is not displayed.

  In the liquid crystal display device of the above embodiment, the right-eye image is displayed on the first image display means 4A disposed on the rear side of the left end side when viewed from the front side of the reflective polarizing screen 1, and the rear side on the right end side. The left image is displayed on the arranged second image display means 4B. Conversely, the left image is displayed on the first image display means 4A, and the second image display means is displayed. An image for the right eye may be displayed on 4B. In this case, the reflective polarizing screen 1 is emitted from the first image display means 4A, transmitted through the screen 1, and incident on the front surface 2 thereof. The image light for the eye is reflected in the direction of the left eye of the display observer C, emitted from the second image display means 4B, transmitted through the screen 1, and incident on the front surface 2 thereof. Curved in a circular arc with a curvature reflecting in the right eye direction of the observer C Bayoi.

  In the embodiment, the reflective polarizing screen 1 is curved in a cylindrical surface shape. However, the reflective polarizing screen 1 is not limited to a cylindrical surface shape, and may be curved in a spherical shape.

  Further, the liquid crystal display device of the embodiment displays a three-dimensional image in front of the display observer C, but the present invention displays a three-dimensional image at a position somewhat distant from the observation position by the display observer. In this case, the reflective polarizing screen 1 and the first and second image display means 4A and 4B are supported by a frame such as a floor-standing type or a wall-mounted type, and the screen 1 The light emitted from the image display means for displaying the right-eye image according to the distance from the observation position, and transmitted through the screen 1 and incident on the front surface 2 in the direction of the right eye of the display observer What is necessary is just to set so that the light which reflected and radiate | emitted from the image display means which displays the image for left eyes, permeate | transmitted the said screen 1, and entered the front surface 2 may be reflected in the left eye direction of a display observer.

(Second embodiment)
3 and 4 show a second embodiment of the present invention. FIG. 3 is a perspective view of the liquid crystal display device, and FIG. 4 is a diagram showing the principle of displaying a three-dimensional image by the liquid crystal display device.

  As shown in FIG. 3, the liquid crystal display device of this embodiment is formed of a film having a front surface 12 facing the display viewing side and a rear surface 13 on the opposite side, and two directions perpendicular to each other along the film surface. Of the two linearly polarized light components of the incident light that are orthogonal to each other, the linearly polarized light component that is parallel to the transmissive axis 11a is transmitted, and the linearly polarized light component that is parallel to the reflective axis 11b. Of the light incident on the front screen 11 from the front surface 12 of the front screen 11 having an optical characteristic to reflect the light and the light incident on the front screen 11 from the front surface 12. A rear screen 14 that reflects light, a liquid crystal display element 16 that controls transmission of light to display an image, and a surface light source 20 that supplies light to the liquid crystal display element 16. The first and second image display means 15A and 15B that emit linearly polarized image light from the liquid crystal display element 16 and the images of the same pattern are displayed on the first and second image display means 15A and 15B, respectively. Display driving means.

  The front screen 11 and the rear screen 14 are reflective polarizing films similar to the reflective polarizing screen 1 in the first embodiment described above, and the rear screen 14 is substantially parallel to the transmission axis 11 a of the front screen 11. A reflection axis 14b in a certain direction and a transmission axis 14a in a direction substantially parallel to the reflection axis 11b of the front screen 11. Hereinafter, the front screen 11 is referred to as a front reflective polarizing screen, and the rear screen 14 is referred to as a rear reflective polarizing screen.

  In this embodiment, the front-side reflective polarizing screen 11 and the rear-side reflective polarizing screen 14 are respectively cylindrical surfaces that are curved in a direction retreating from both ends toward the opposite side from the display viewing side toward the center. It is a screen.

  The liquid crystal display elements 16 of the first and second image display means 15A and 15B each have a liquid crystal cell 17 having a plurality of pixels (not shown) arranged in a matrix in the row and column directions. It consists of a pair of polarizing plates 18 and 19 on the incident side and the emission side, which are arranged with the liquid crystal cell 17 interposed therebetween.

  The liquid crystal display element 16 of the first and second image display means 15A and 15B is, for example, a TN type active matrix liquid crystal display element, and the configuration thereof is the first and second images in the first embodiment. This is the same as the liquid crystal display element 5 of the display means 4A, 4B.

  The surface light sources 20 of the first and second image display means 15A and 15B have the same configuration as the surface light sources 9 of the first and second image display means 4A and 4B in the first embodiment, respectively. The surface light source 20 is arranged on the incident surface side of the liquid crystal display element 16 so that the exit surface of the light guide plate described above is closely opposed to the incident surface of the liquid crystal display element 16 (the outer surface of the incident-side polarizing plate 18). Has been.

  That is, each of the first and second image display means 15A and 15B causes the light emitted from the surface light source 20 to enter the liquid crystal display element 16 from the incident surface side, and transmits the light to the liquid crystal cell 17. The image is displayed on the liquid crystal display element 16 by controlling according to the image data (electric field applied between the electrodes of each pixel) written to each pixel of the liquid crystal display element 16. Then, linearly polarized image light parallel to the transmission axis 19 a of the emission side polarizing plate 19 is emitted.

  Of the first and second image display means 15A and 15B, the first image display means 15A is provided on one end side of the front reflective polarizing screen 11, for example, on the left end side when viewed from the front side of the front reflective polarizing screen 11. The image light is emitted from the first image display means 15A in a state where the edge on the right side as viewed from the emission side of the liquid crystal display element 16 is brought close to the edge of the front reflective polarizing screen 11 in front. The second image display means 15B is disposed at the right end when viewed from the other end side of the front reflective polarizing screen 11, that is, from the front side of the front reflective polarizing screen 11. In front of the second image display means 15B, the left edge viewed from the emission side of the liquid crystal display element 16 is close to the edge of the front reflective polarizing screen 11. The emission direction of the image light is directed toward the front surface 12 of the front reflection polarizing screen 11.

  In this liquid crystal display device, the first image display unit disposed in front of one of the first and second image display units 15A and 15B, for example, the left end side of the front reflective polarizing screen 11 is used. The vibration direction of the linearly polarized light emitted from the means 15A (the direction parallel to the transmission axis 19a of the emission side polarizing plate 19 of the liquid crystal display element 16 of the first image display means 15A) is reflected on the reflection axis 11b of the front reflection polarizing screen 11. And the direction of vibration of the linearly polarized light emitted from the other image display means, that is, the second image display means 15B arranged in front of the right end side of the front reflective polarizing screen 11 (second The liquid crystal display element 16 of the image display means 15B is substantially parallel to the transmission axis 11a of the front reflective polarizing screen 11) (in a direction parallel to the transmission axis 19a of the output-side polarizing plate 19). It is constant.

  Further, display driving means for displaying the same pattern image on the first and second image display means 15A and 15B, respectively, is a first display driving circuit 21A for driving the first image display means 15A, and It comprises a second display driving circuit 21B for driving the second image display means 15B.

  Although the configuration of each of the first and second display driving circuits 21A and 21B is not shown, each gate wiring of the liquid crystal cell 17 of the liquid crystal display element 16 is sequentially selected to supply a gate signal, and each of the gates Corresponding to the selection of the wiring, a data signal corresponding to image information supplied from the outside is supplied to each data wiring to write image data to each pixel, and a light emitting element of the surface light source 20 A display light source driving section for lighting the display element driving sections of the display driving circuits 21A and 21B. The liquid crystal display element 16 of the first image display means 15A and the liquid crystal display of the second image display means 15B. The same image data is written to each of the elements 16.

  Each of the surface light source drive units of the first and second display drive circuits 21A and 21B is configured to be able to adjust the light intensity emitted from the surface light source 20 (the light intensity emitted from the light emitting element). Further, the surface light source drive unit of the second display drive circuit 21B has a lower intensity than the light emitted from the surface light source 20 of the second image display means 15B and from the surface light source 20 of the first image display means 15A. It is configured to emit light.

  That is, the display driving means including the first and second display driving circuits 21A and 21B has the same pattern as the first and second image display means 15A and 15B, and the front reflective polarizing screen 11 has the same pattern. Second linear light that emits linearly polarized light substantially parallel to the transmission axis 11a of the front reflective polarizing screen 11 rather than the display luminance of the first image display means 15A that emits linearly polarized light substantially parallel to the reflective axis 11b. The image display means 15B is configured to display an image with low display brightness.

  As a method for making the display brightness of the second image display means 15B lower than the display brightness of the first image display means 15A, data supplied to the liquid crystal display element 16 of the first image display means 15A. It is also conceivable to control the transmittance of each liquid crystal display element 16 to a different value by making the voltage value of the signal different from the voltage value of the data signal supplied to the liquid crystal display element 16 of the second image display means 15B. However, in terms of ease of display driving, it is advantageous to vary the intensity of light emitted from the surface light sources 20 of the first and second image display means 15A and 15B as described above.

  In the liquid crystal display device of this embodiment as well, the liquid crystal display elements 16 of the first and second image display means 15A and 15B each have a color image display provided with three color filters of red, green and blue. The device may be a field sequential display device that displays a color image without providing a color filter, and the first and second display driving circuits 21A and 21B are described in the first embodiment. What is necessary is just to comprise.

  Further, the liquid crystal display device of this embodiment displays a three-dimensional image in front of the face of the display observer D (see FIG. 4). The front reflective polarizing screen 11, the rear reflective polarizing screen 14, and the first The second image display means 15A and 15B are provided on a mounting body (not shown) mounted in front of the eyes of the display observer D, for example.

  The liquid crystal display device of this embodiment displays images of the same pattern on the first and second image display means 15A and 15B, respectively, and the image light from these image display means 15A and 15B is displayed on the front reflective polarizing screen. 11, the image light emitted from the first image display means 15A is reflected to the observation side by the front reflective polarizing screen 11, and the image light emitted from the second image display means 15B is made incident on the front surface 12. The reflected light is transmitted through the front reflective polarizing screen 11 and reflected to the viewing side by the rear reflective polarizing screen 14, and the display observer D receives the reflected image from the front reflective polarizing screen 11 and the reflected image from the rear reflective polarizing screen 14. In this liquid crystal display device, the cylindrical surface shape can be observed. The curvatures of the front and rear reflective polarizing screens 11 and 14 and the positional relationship between the reflective polarizing screens 11 and 14 and the first and second image display means 15A and 15B are reflected by the front reflective polarizing screen 11. And the reflection image by the rear reflective polarizing screen 14 are set so as to appear to overlap each other.

  The display of a three-dimensional image by this liquid crystal display device will be described with reference to FIG. 4. This liquid crystal display device has the same pattern on the first image display means 4A and the second image display means 4B, and An image having a lower brightness of the second image display means 15B than the brightness of the first image display means 15A is displayed at the same time, and the first image disposed in front of the left end side of the front reflective polarizing screen 11 is displayed. As shown by the solid line in FIG. 4, the image light emitted from the image display means 15A enters the front reflective polarizing screen 11 from the front surface 12 and forwards on the right end side of the front reflective polarizing screen 11. The image light emitted from the arranged second image display means 15B enters the front reflective polarizing screen 11 from the front surface 12 as shown by the broken line in FIG.

  Each of these image lights is linearly polarized light having a vibration plane parallel to the transmission axis 19a of the exit-side polarizing plate 19 of the liquid crystal display element 16 of the first and second image display means 15A, 15B. In the display device, of the first and second image display means 15A and 15B, the vibration direction of the linearly polarized light emitted from the first image display means 15A is the front side as indicated by a chain line arrow a1 in FIG. The front-side reflective polarizing screen 11 is substantially parallel to the reflective axis 11b of the reflective polarizing screen 11, and the vibration direction of the linearly polarized light emitted from the second image display means 15B is indicated by a chain line arrow a2 in FIG. The linearly polarized light emitted from the first image display means 15A and incident on the front reflective polarizing screen 11 from its front surface 12 is substantially parallel to the transmission axis 11a of the The linearly polarized light that is reflected to the observation side by the reflective polarizing screen 11 and is emitted from the second image display means 15B and incident on the front reflective polarizing screen 11 from the front surface 12 is transmitted through the front reflective polarizing screen 11. Then, the light enters the rear reflective polarizing screen 14.

  In this liquid crystal display device, since the reflection axis 14b of the rear reflective polarizing screen 14 is substantially parallel to the transmission axis 11a of the front reflective polarizing screen 11, the light is emitted from the second image display means 15B. Then, the linearly polarized light transmitted through the front reflective polarizing screen 11 and incident on the rear reflective polarizing screen 14 is reflected by the rear reflective polarizing screen 14 to the observation side, and transmitted again through the front reflective polarizing screen 11 for observation. To the side.

  That is, in this liquid crystal display device, the vibration direction of the linearly polarized light emitted from the first image display means 15A is substantially parallel to the reflection axis 11b of the front reflective polarizing screen 11, and the second image display means 15B The direction of oscillation of the emitted linearly polarized light is substantially parallel to the transmission axis 11 a of the front reflective polarizing screen 11, and the reflection axis 14 b of the rear reflective polarizing screen 14 is substantially parallel to the transmission axis 11 a of the front reflective polarizing screen 11. Therefore, the image light emitted from the first image display means 15A is reflected by the front reflective polarizing screen 11 and emitted to the observation side, and the image emitted from the second image display means 15B. Light is transmitted through the front reflective polarizing screen 11 and reflected by the rear reflective polarizing screen 14, and the light is reflected by the front reflective polarized light. Can be emitted to the observation side a clean 11 is again transmitted.

  In this liquid crystal display device, the curvatures of the front and rear reflective polarizing screens 11 and 14 and the positional relationship between the reflective polarizing screens 11 and 14 and the first and second image display means 15A and 15B are represented by the front side. Since the reflected image by the reflective polarizing screen 11 and the reflected image by the rear reflective polarizing screen 14 are set so as to overlap each other, the display observer D emits from the first image display means 15A and reflects the front side. An image reflected on the viewing side by the polarizing screen 11 and an image emitted from the second image display means 15B and reflected on the viewing side by the rear reflecting polarizing screen 14 are extremely in accordance with the viewing angle of display. It is possible to observe a three-dimensional image with a sense of depth that overlaps with a slight shift.

  Moreover, in the liquid crystal display device, as described above, the first image display unit 4A and the second image display unit 4B have the same pattern and the luminance of the first image display unit 15A is higher than that of the first image display unit 15A. Since the second image display means 15B displays an image with low brightness, a high brightness image emitted from the first image display means 15A and reflected to the observation side by the front reflective polarizing screen 11 and A three-dimensional image emphasizing the sense of depth is displayed in which the low-luminance image emitted from the second image display means 15B and reflected to the observation side by the rear reflective polarizing screen 14 is overlapped with a slight deviation. be able to.

  The depth feeling of the three-dimensional image becomes stronger as the luminance difference between the display images of the first and second image display means 15A and 15B is increased. 3D images with a sense of depth can be displayed.

  As described above, the liquid crystal display device has the transmission axis 11a and the reflection axis 11b in two directions orthogonal to each other, and is a straight line parallel to the transmission axis 11a among two linearly polarized light components of incident light orthogonal to each other. A front reflective polarizing screen 11 having an optical characteristic of transmitting a polarized light component and reflecting a linearly polarized light component parallel to the reflection axis 11b, and a rear side of the front reflective polarizing screen 11 spaced apart from each other. And a rear reflective polarizing screen 14 that reflects the light transmitted through the front reflective polarizing screen 11. The front reflective polarizing screen 11 has a front end on one end side and a front side on the other end side. The first image display means 15A and the second image display means 15B that emit linearly polarized image light are used to output image light from the respective image display means 15A and 15B. The direction is arranged toward the front surface 12 of the front reflective polarizing screen 11, and the vibration direction of the linearly polarized light emitted from one of the first and second image display means 15A, 15B is output from one image display means 15A. It is set substantially parallel to the reflection axis 11b of the front reflective polarizing screen 11, and the vibration direction of the linearly polarized light emitted from the other image display means 15B is substantially parallel to the transmission axis 11a of the front reflective polarizing screen 11. The image of the same pattern is displayed on the first and second image display means 15A and 15B, respectively, and the image light from these image display means 15A and 15B is displayed on the front reflective polarizing screen 11 on the front surface 12 thereof. The image light emitted from one of the image display means 15A is observed by the front reflective polarizing screen 11 The image light reflected from the other image display means 15B is transmitted through the front reflective polarizing screen 11 and reflected to the observation side by the rear reflective polarizing screen 14, and is reflected to the display observer D by the front reflection. A three-dimensional image with a sense of depth in which a reflected image by the polarizing screen 11 and a reflected image by the rear reflective polarizing screen 14 are overlapped is observed.

  Therefore, according to this liquid crystal display device, the first and second image display means 15A and 15B each display a precise image having the same dot pitch as the pixel pitch of the liquid crystal display element 16, thereby providing a high-resolution three-dimensional image. An image can be displayed.

  In addition, in this liquid crystal display device, images of the same pattern are displayed on the first and second image display means 15A and 15B, respectively, and image light emitted from one image display means 15A is transmitted by the front reflective polarizing screen 11. The image light reflected to the observation side and emitted from the other image display means 15B is transmitted through the front reflective polarizing screen 11 and reflected to the observation side by the rear reflective polarizing screen 14. The positional relationship between the reflective polarizing screens 11 and 14 on the side and the first and second image display means 15A and 15B is as follows: the reflected image by the front reflective polarizing screen 11 and the reflected image by the rear reflective polarizing screen 14 What is necessary is just to set so that it may overlap, Therefore, it can manufacture easily.

  In the liquid crystal display device of the above embodiment, the display driving means including the first and second display driving circuits 21A and 21B is connected to the first and second image display means 15A and 15B. A first linearly polarized light that is substantially parallel to the transmission axis 11a of the front reflective polarizing screen 11 is emitted from the luminance of the first image display means 15A that emits linearly polarized light that is substantially parallel to the reflection axis 11b of the screen 11. Since the second image display unit 15B is configured to display an image with low luminance, a three-dimensional image with enhanced depth can be displayed.

  Further, in the liquid crystal display device of the above-described embodiment, the front reflective polarizing screen 11 and the rear reflective polarizing screen 14 are respectively curved in a direction of retreating from the opposite ends toward the opposite side from the display viewing side toward the central portion. Therefore, the image light reflected by the front reflective polarizing screen 11 and the image light reflected by the rear reflective polarizing screen 14 are condensed in front of the central portions of the screens 11 and 14 to obtain a brighter tertiary image. The original image can be displayed.

  The liquid crystal display device can display not only the three-dimensional image but also a two-dimensional image. In this case, either one of the first and second image display means 15A and 15B has a high luminance. An image may be displayed and the other may be hidden.

  Further, the liquid crystal display device can display a three-dimensional image with a sense of depth on the entire screen, or can display a three-dimensional image with a sense of depth in a predetermined region in the screen, for example, A low-brightness image over the entire screen is displayed on one image display means 15A that emits linearly polarized light substantially parallel to the reflection axis 11b of the front reflective polarizing screen 11, and substantially the same as the transmission axis 11a of the front reflective polarizing screen 11. A high-luminance image having the same pattern as the display image of the corresponding portion of the one image display means 15A is displayed on a part of the screen of the other image display means 15B that emits linearly polarized light that is parallel to the other image. By displaying the other area of the screen of the display means 15B in black, a part of the screen can be seen as a three-dimensional image with a sense of depth, and the other area is the same as the two-dimensional background image. Image that looks Te can be displayed.

  In the liquid crystal display device of the above embodiment, the front and rear reflective polarizing screens 11 and 14 are curved in a cylindrical surface shape. However, the reflective polarizing screens 11 and 14 are not limited to a cylindrical surface screen. As long as the images reflected by both the reflective polarizing screens 11 and 14 overlap and can be seen by a display observer, for example, a spherical screen or the like may be used.

  Further, in the above embodiment, the rear screen 14 has a reflection axis 14b in a direction substantially parallel to the transmission axis 11a of the front reflection polarizing screen 11, and substantially has the reflection axis 11b of the front reflection polarization screen 11. Although the reflective polarizing screen has a transmission axis 14a in a parallel direction, the light reflected by the rear screen 14 is linearly polarized light substantially parallel to the transmission axis 11a of the front reflective polarizing screen 11, The rear screen 14 may be a reflective screen made of a mirror film.

  The liquid crystal display device of the above embodiment displays a three-dimensional image in front of the display observer D, but the present invention displays the three-dimensional image at a position somewhat away from the observation position by the display observer. The present invention can also be applied to a display liquid crystal display device. In this case, the front and rear reflective polarizing screens 11 and 14 and the first and second image display means 15A and 15B are mounted on a frame such as a floor-standing type or a wall-mounted type. It only has to be supported.

  DESCRIPTION OF SYMBOLS 1 ... Reflective polarizing screen, 1a ... Transmission axis, 1b ... Reflection axis, 2 ... Front surface, 3 ... Rear surface, 4A, 4B ... Image display means, 5 ... Liquid crystal display element, 6 ... Liquid crystal cell, 7, 8 ... Polarizing plate, 8a ... transmission axis of the exit side polarizing plate, 9 ... surface light source, 10A, 10B ... display drive circuit (display drive means), 11 ... front reflective polarizing screen, 11a ... transmission axis, 11b ... reflection axis, 12 ... front surface, 13 ... rear surface, 14 ... rear reflective polarizing screen, 14a ... transmission axis, 14b ... reflection axis, 15A, 15B ... image display means, 16 ... liquid crystal display element, 17 ... liquid crystal cell, 18, 19 ... polarizing plate, 19a ... emission Transmission axis of side polarizing plate, 20... Surface light source, 21A, 21B... Display drive circuit (display drive means).

Claims (2)

A reflective polarizing film arranged to bend toward a predetermined direction;
A first image projection means arranged so that a light exit region faces a first region of the reflective polarizing film and a second region different from the first region;
The reflected polarized light is disposed between the first image projecting unit and the third region of the reflective polarizing film so as to oppose a third region of the reflective polarizing film and a fourth region different from the third region. Second image projecting means arranged so that the film is interposed;
With
In the first image projecting unit, the inner surface of the reflective polarizing film in the second region is set as a projection surface, and the light emitted from the first image projecting unit is incident on the second region. Arranged so that the first region is located on the optical path leading to
In the second image projection unit, an inner surface of the reflective polarizing film in the fourth region is set as a projection surface, and light emitted from the second image projection unit is incident on the fourth region. A liquid crystal display device, characterized in that the third region is positioned on the optical path to the end. The first image projection means emits light that is transmitted through the first region and reflected by the second region;
The liquid crystal display device according to claim 1, wherein the second image projection unit emits light that is transmitted through the third region and reflected by the fourth region.

Images